DE102017211764B4 - C-arm for a medical examination or treatment facility - Google Patents

Abstract

C-arm for a medical examination or treatment device, which is designed as a metal casting component (7), characterized in that one or more stiffening profiles (10) extending at least in sections along the C-arm (2) are cast.

Description

The invention relates to a C-arm for a medical examination or treatment device, which is designed as a cast metal component.

Various medical examination or treatment devices have a C-arm on which corresponding examination or treatment devices, for example a radiation source and a radiation receiver, are arranged, which can be moved in space via the C-arm. An example of this are X-ray devices with an X-ray source and an X-ray receiver. They are used to record fluoroscopic images. The C-arm is usually arranged on a movement device, for example a tripod or a multi-axis steering arm, via which, since the tripod or the articulated arm can be moved by several degrees of freedom, it can be moved in space so that the equipment arranged on the arch can be moved towards the patient can be positioned.

It is known to produce such a C-arm by extrusion and subsequent rolling of the C-arm shape or as a cast metal component, usually made of aluminum. The maximum height of the cross-sectional profile of the C-arm is determined, among other things, by the isocenter height and the minimum insertion radius. The arch width, in turn, is defined by the necessary mobility with regard to the movement angle to be covered.

In various examination or treatment processes, the C-arm is moved around the patient at high speed in order to record 3D images. Increasingly higher demands are made here with regard to the rigidity and the increase in the natural frequency of the C-arm in order to achieve the desired image quality and, in particular, smoothness. So that the rigidity of the C-arm can be increased, it is necessary to increase the wall thickness accordingly, which on the one hand makes the production of the C-arm increasingly difficult and inevitably would also result in a considerable increase in weight, i.e. the moving mass over it increases, which is disadvantageous. On the other hand, the natural frequency would be reduced again, which is also disadvantageous with regard to a stable arc movement.

Out DE 10 2008 003 816 A1 An X-ray device comprising a C-arm rotatably mounted on a robot arm is known, the interior of the at least partially hollow C-arm being accessible from at least one access side to enable integration of at least part of the electronic components used to operate the radiation source and the radiation receiver in the interior of the arch . The C-arm, consisting of two separate arched sections connected to one another to form an arch, has struts arranged like a framework on the access side.

It is also off DE 20 2015 008 455 U1 a hybrid C-arm for a medical imaging device is known which has at least one carbon fiber-reinforced plastic part which is fixedly arranged in or on the wall of the C-arm.

The invention is thus based on the problem of specifying a C-arm which is improved in comparison.

To solve this problem, a C-arm for a medical examination or treatment device is provided according to the invention, which is designed as a metal cast component, with one or more stiffening profiles extending at least in sections along the C-arm being cast.

The C-arm according to the invention is produced as a cast metal component, preferably made of aluminum. It is characterized in that one, preferably several reinforcement profiles are cast into the cast metal component. These stiffening profiles extend along the C-arm, that is to say are shaped in accordance with the arch shape, whereby they preferably extend over almost the entire length of the arch. By pouring this or these stiffening profiles, which are preferably positioned as far away as possible from the neutral fiber of the arch, the rigidity of the C-arm can be significantly increased. The increase in weight resulting from the pouring in of the stiffening profiles is acceptable to negligible, since the stiffening profiles only make up a small part of the weight of the arch.

By integrating or pouring in this or these stiffening profiles, the C-arm can consequently be retained in its desired dimension, an increase in wall thickness and the like to increase rigidity is not necessary. At the same time, the C-arm is significantly stiffer compared to a pure metal cast component and can easily meet the requirements placed on it, even for movements at very high speeds.

The reinforcement profile or profiles are preferably hollow profiles, in particular with a rectangular or square cross-section, which has an advantageous effect on an only imperceptible increase in weight.

To increase the rigidity, the reinforcement profile or profiles preferably have a modulus of elasticity that is significantly higher than that of the cast metal component. This is preferably made of aluminum, while the reinforcement profile or profiles are preferably made of steel.

The arch itself preferably has a rectangular hollow cross-section, in which case four stiffening profiles are preferably provided, which are arranged in a rectangular shape, that is to say in the region of the corners of the rectangular C-arm. They are therefore located in the area of the edge fibers and outside the neutral fibers, which is advantageous for the stiffening of the arch.

An expedient further development provides for two adjacent stiffening profiles to be connected to one another via one or more connecting elements. This means that a stiffening skeleton is cast into the cast metal component, consisting in this case of several stiffening profiles, in particular in the form of hollow profiles, which are connected to one another either locally or over their entire length via corresponding connecting elements. These connecting elements can be connected to the stiffening profiles by welding or adhesive connections, so they are preferably made of the same material as the stiffening profiles. Such connecting profiles are, for example, metal sheets or plates, which preferably have corresponding openings in order to enable the casting material to pass through. Corresponding perforated web plates or web plates are used that connect the stiffening profiles. In the case of a rectangular cross-sectional shape of the arch, a cast-in, likewise rectangular reinforcement geometry results.

The C-arm according to the invention is characterized overall by a significantly increased rigidity when subjected to bending or torsion stress. The natural frequency can also be increased by integrating the stiffening profile (s), possibly also the stiffening element (s), which also has a positive effect on the movement and thus the image recording operation. The height of the C-arm profile and thus the isocenter height can also be reduced while maintaining the same system rigidity, since of course there is also the possibility of configuring the C-arm overall to be significantly narrower or slimmer by pouring in the stiffening components, with the same, previously given rigidity has a beneficial effect on the arch height and the isocenter height.

• - Einbringen eines oder mehrerer sich zumindest abschnittsweise längs des fertigen C-Bogens erstreckender Versteifungsprofile in eine Gießform, und
• - Gießen des C-Bogens unter Einbettung des oder der Versteifungsprofile in der Gießform.

In addition to the C-arm itself, the invention also relates to a method for producing such a C-arm in a metal casting process, with the following steps:

• Introducing one or more stiffening profiles extending at least in sections along the finished C-arm into a casting mold, and
• - Casting of the C-arm with embedding of the reinforcement profile or profiles in the casting mold.

For the actual arch casting, the stiffening profile (s), regardless of how they are specifically shaped in cross-section or how far they extend in sections around the finished arch, and possibly additional stiffening elements, which will be discussed below, are introduced into the mold and positioned . The mold is then filled with the metal, usually aluminum, of course, so that the corresponding stiffening components are embedded and the finished, sufficiently stiffened C-arm is produced.

The stiffening profile or stiffening profiles used are preferably hollow profiles, preferably with a square and, in particular, a square cross section.

The arch itself is, as described, preferably cast from aluminum, while the stiffening profile or stiffening profiles used are those made of steel, i.e. profiles that have a significantly higher modulus of elasticity than the cast metal component or the cast material.

The stiffening profiles are preferably arranged in a rectangular shape and cast in the area of the corners of the C-arm, which has a rectangular high cross section, which is particularly useful for increasing the rigidity.

Finally, two adjacent stiffening profiles can be connected to one another via one or more connecting elements, which connecting elements are also cast in. These connecting elements are preferably also made of the same material as the stiffening profiles, that is to say preferably also made of steel, and are glued or welded to them. If, for example, four stiffening profiles are positioned in the area of the arch corners, they are connected to a rectangular shape via corresponding connecting elements, so that a quasi-rectangular stiffening skeleton is obtained, preferably extending along almost the entire arch length.

Sheets or plates can preferably be used as connecting profiles, which are preferably provided with openings, that is, perforated sheet metal or perforated plates.

In addition to the method, the invention finally relates to a medical examination and / or treatment device comprising a C-arm of the type described.

• 1 eine Prinzipdarstellung einer erfindungsgemäßen medizinischen Untersuchungs- oder Behandlungseinrichtung umfassend einen erfindungsgemäßen C-Bogen,
• 2 eine Schnittansicht durch einen erfindungsgemäßen C-Bogen einer ersten Ausführungsform, und
• 3 eine Schnittansicht durch einen erfindungsgemäßen C-Bogen einer zweiten Ausführungsform.

Further advantages and details of the present invention emerge from the exemplary embodiments described below and on the basis of the drawings. Show:

• 1 a schematic diagram of a medical examination or treatment device according to the invention comprising a C-arm according to the invention,
• 2 a sectional view through a C-arm according to the invention of a first embodiment, and
• 3rd a sectional view through a C-arm according to the invention of a second embodiment.

1 shows a medical examination and / or treatment device according to the invention 1 , comprising a C-arm 2 , on the example shown, a radiation source 3rd as well as a radiation receiver 4th , for example an X-ray source and an X-ray receiver, are arranged. The C-arm 2 is on a base frame 5 arranged with which he has a corresponding connection 6th is coupled. With this connection 6th , which is shown here only in principle, it can be, for example, a multi-joint arm or a tripod or the like. In any case, the C-arm is via this connection 6th movable in space. On the one hand, it is along its arched path, as indicated by the double arrow P1 is shown, movable, that is movable on an orbital path, so that it can be rotated about the isocenter I. In addition, it can also be rotated around an axis, as indicated by the arrow P2 shown. In the case of an articulated arm, this is the C-arm 2 can be moved around further axes, also in the case of a tripod. 1 shows only a pure principle representation in order to show the basic possibilities of movement of the C-arm. Because from these movement possibilities, in particular the sometimes very fast orbital movement along the arrow P1 , there are corresponding requirements for the rigidity of the C-arm 2 .

A first example of a C-arm 2 is in a cross-sectional view in 1 shown. The C-arm 2 consists of or is a cast metal component 7th executed, it is an aluminum casting that is produced in a corresponding casting mold. There are corresponding guide projections in the area of the lateral end 8th shown on corresponding linear guides 9 , which are only shown here as an example, run when the C-arm 2 along the orbital path according to the arrow P1 is moved.

The C-arm clearly points 2 a hollow rectangular profile, so it is a hollow body. There are stiffening profiles in the area of the four corners of the cast metal component 10 cast, which are also rectangular hollow profiles and which are made of a material that has a significantly higher modulus of elasticity than cast aluminum material, preferably steel profiles. These metal stiffening profiles 10 are in the correspondingly reinforced corner areas of the C-arm 2 , i.e. cast or embedded in the casting material in the area of the edge fibers. They extend at least in sections, preferably almost over the entire length of the C-arm, over which this is very well stiffened, so that it also meets high movement requirements. The wall thickness of the stiffening profiles 10 is between 2 - 5 mm.

3rd shows a further cross-sectional view through a C-arm 2 a second embodiment according to the invention, the same reference numerals being used for the same components. This C-arm too 2 is a cast metal component 7th executed, so has a metal cast body. Again there are corresponding lateral guide sections 8th for the appropriate guidance in the area of the connection 6th intended. Here, too, is the C-arm 2 designed as a hollow body with a rectangular cross-sectional shape.

As in the example according to 2 are also here in the area of the corners the corresponding rectangular, here also square stiffening profiles 10 encapsulated or embedded in the form of corresponding hollow bodies, with the encapsulation also taking place here on all sides. Unlike the design according to 1 However, there are two adjacent stiffening profiles 10 via additional stiffening elements 11 connected to one another in the form of flat plates or sheets. The fasteners 11 preferably have a thickness which corresponds to the thickness of the stiffening profiles when they are designed as hollow profiles. The connection is made by welding or gluing, for which purpose the stiffening elements are preferably made of the same material, that is to say also made of steel, as the hollow stiffening profiles 10 . You can see the stiffening profiles along the C-arm 10 Only connect locally or in sections, but you can also connect them over the entire length of the arch or profile. The stiffening elements 10 are preferably provided with openings, i.e. perforated, so that the cast metal material can pass through accordingly.

The result is a kind of reinforcement skeleton that is completely embedded or cast on all sides in the cast metal body.

The stiffening profiles are used for production 10 and, if present, also the connecting elements already attached to them, as which can sometimes be used with correspondingly narrow rods, inserted into a corresponding casting mold and positioned, after which the actual potting takes place.
Although the invention has been illustrated and described in more detail by the preferred exemplary embodiment, the invention is not restricted by the disclosed examples and other variations can be derived therefrom by the person skilled in the art without departing from the scope of protection of the invention.

Claims (15)

C-arm for a medical examination or treatment device, which is designed as a metal casting component (7), characterized in that one or more stiffening profiles (10) extending at least in sections along the C-arm (2) are cast. C-arm according to Claim 1 , characterized in that the stiffening profile or profiles (10) are hollow profiles. C-arm according to Claim 1 or 2 , characterized in that the cast metal component (7) is made of aluminum and the reinforcing profile or profiles (10) are made of steel. C-arm according to one of the preceding claims, characterized in that the C-arm (2) has a rectangular hollow cross-section, and that four stiffening profiles (10) are provided which are arranged in a rectangular shape. C-arm according to one of the preceding claims, characterized in that two adjacent stiffening profiles (10) are connected to one another via one or more connecting elements (11). C-arm according to Claim 5 , characterized in that the connecting element or elements (11) are metal sheets or plates. C-arm according to Claim 6 , characterized in that the sheets or plates have openings. Process for the production of a C-arm for a medical examination or treatment facility in a metal casting process, with the following steps: - Introducing one or more stiffening profiles (10) extending at least in sections along the finished C-arm (2) into a casting mold, and - Casting the C-arm with the embedding of the stiffening profile or profiles (10) in the casting mold. Procedure according to Claim 8 , characterized in that hollow profiles are used as stiffening profile (10) or stiffening profiles (10). Procedure according to Claim 8 or 9 , characterized in that the C-arm (2) is cast from aluminum and a stiffening profile (10) or stiffening profiles (10) made of steel are used. Method according to one of the Claims 8 to 10 , characterized in that the stiffening profiles (10) are arranged in a rectangular shape and cast in the region of the corners of the C-arm (2) which has a rectangular hollow cross-section. Method according to one of the Claims 8 to 11 , characterized in that two adjacent stiffening profiles (10) are connected to one another via one or more connecting elements (11), which connecting elements (11) are also cast in. Procedure according to Claim 12 , characterized in that sheets or plates are used as connecting elements (11). Procedure according to Claim 13 , characterized in that sheets or plates with perforations are used. Medical examination and / or treatment device comprising a C-arm (2) according to one of the Claims 1 to 7th .

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